An anti-corrosion structure of a gas sensor is provided. The gas sensor includes a hollow cylindrical air cover assembly made up of an inner and an outer cover. The air cover assembly has formed therein air inlets through which air is admitted into the gas sensor. The inner and outer covers are joined together through at least one crimped portion which defines a water drain path extending from the air inlets to outside the air cover assembly, thereby draining the water entering at the air inlets out of the gas sensor. This avoids accumulation of the water between the inner and outer covers to minimize gap corrosion therebetween.
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2. A gas sensor comprising:
a sensor element sensitive to a gas to produce a signal as a function of concentration of the gas, said sensor element having a length with a top end and a base end opposite the top end;
a housing in which said sensor element is retained, said housing having a top end and a base end opposite the top end;
an air cover assembly having a top end and a base end opposite the top end, said air cover assembly being made up of an inner cover and an outer cover, the inner cover being secured to the base end of said housing, the outer cover surrounding the inner cover and being joined to the inner cover through a crimped portion which extends over the whole of a periphery of said air cover assembly;
an air inlet formed in a portion of said air cover assembly which is closer to the base end of said air cover assembly than the crimped portion, the air inlet being designed to admit air into said air cover assembly; and
a water drain hole formed in said air cover assembly to establish fluid communication of outside said air cover assembly with a clearance extending from the crimped portion to said air inlet between the inner and outer covers of said air cover assembly.
1. A gas sensor comprising:
a sensor element sensitive to a gas to produce a signal as a function of concentration of the gas, said sensor element having a length with a top end and a base end opposite the top end;
a housing in which said sensor element is retained, said housing having a top end and a base end opposite the top end;
an air cover assembly having a top end and a base end opposite the top end, said air cover assembly being made up of an inner cover and an outer cover, the inner cover being secured to the base end of said housing, the outer cover surrounding the inner cover and being joined to the inner cover through at least one crimped portion;
an air inlet formed in a portion of said air cover assembly which is closer to the base end of said air cover assembly than the crimped portion, the air inlet being designed to admit air into said air cover assembly; and
an air chamber defined by the crimped portion between the inner and outer covers of said air cover assembly from the crimped portion circumferentially of said air cover assembly, said air chamber being exposed outside said air cover assembly at a side opposite said air inlet across the crimped portion to define a water drain path establishing fluid communication between said air inlet and outside said air cover assembly.
3. A gas sensor as set forth in
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The present application claims the benefit of Japanese Patent Application No. 2006-99193 filed on Mar. 31, 2006, the disclosures of which are incorporated herein by reference.
1. Technical Field of the Invention
The present invention relates generally to a gas sensor which may be employed in measuring the concentration of a selected component of exhaust gasses emitted from automotive engines, and more particularly to an anti-corrosion structure of such a gas sensor.
2. Background Art
Japanese Patent First Publication No. 10-10082 discloses a gas sensor to be installed in an exhaust pipe of an internal combustion engine for automotive vehicles to measure the concentration of a given gas component of exhaust emissions.
The gas sensor 9 consists essentially of a sensor element (not shown) to measure the concentration of a gas (will also be referred to below as a measurement gas), a housing (not shown) in which the sensor element is retained, and an air cover assembly 94 joined to a base end of the housing.
The air cover assembly 94 is, as illustrated in
The inner cover 941 and the outer cover 942 have portions 943 crimped circumferentially thereof.
However, when air is introduced into the gas sensor 9 from air inlets 945 formed in a base end portion of the outer cover 942, water 7 may enter a clearance between the inner cover 941 and the outer cover 942 along a path, as indicated by a thick line W and accumulate, as clearly illustrated in
It is therefore a principal object of the invention to avoid the disadvantages of the prior art.
It is another object of the invention to provide an improved structure of a gas sensor designed to minimize gap corrosion between an inner cover and an outer cover of an air cover assembly.
According to one aspect of the invention, there is provided a gas sensor which may be employed in measuring the concentration of a component of exhaust gasses emitted from automotive engines. The gas sensor comprises: (a) a sensor element sensitive to a gas to produce a signal as a function of concentration of the gas, the sensor element having a length with a top end and a base end opposite the top end; (b) a housing in which the sensor element is retained, the housing having a top end and a base end opposite the top end; (c) an air cover assembly having a top end and a base end opposite the top end, the air cover assembly being made up of an inner cover and an outer cover, the inner cover being secured to the base end of the housing, the outer cover surrounding the inner cover and being joined to the inner cover through at least one crimped portion; (d) an air inlet formed in a portion of the air cover assembly which is closer to the base end of the air cover assembly than the crimped portion, the air inlet being designed to admit air into the air cover assembly; and (e) an air chamber defined by the crimped portion between the inner and outer covers of the air cover assembly from the crimped portion circumferentially of the air cover assembly. The air chamber is exposed outside the air cover assembly at a side opposite the air inlet across the crimped portion to define a water drain path establishing fluid communication between the air inlet and outside the air cover assembly.
The crimped portion is formed to occupy only a portion of the circumference of the air cover assembly, thereby defining the air chamber in which the water drain path extends from the air inlet to outside the air cover assembly. When the water enters at the air inlet, it will flow between the inner and outer covers along the water drain path and drain out of the air cover assembly, thereby minimizing gap corrosion between the inner and outer covers of the air cover assembly.
According to another aspect of the invention, there is provided a gas sensor which comprises: (a) a sensor element sensitive to a gas to produce a signal as a function of concentration of the gas, the sensor element having a length with a top end and a base end opposite the top end; (b) a housing in which the sensor element is retained, the housing having a top end and a base end opposite the top end; (c) an air cover assembly having a top end and a base end opposite the top end, the air cover assembly being made up of an inner cover and an outer cover, the inner cover being secured to the base end of the housing, the outer cover surrounding the inner cover and being joined to the inner cover through a crimped portion which extends over the whole of a periphery of the air cover assembly; (d) an air inlet formed in a portion of the air cover assembly which is closer to the base end of the air cover assembly than the crimped portion, the air inlet being designed to admit air into the air cover assembly; and (e) a water drain hole formed in the air cover assembly to establish fluid communication of outside the air cover assembly with a clearance extending from the crimped portion to the air inlet between the inner and outer covers of the air cover assembly.
When the water enters at the air inlet, it will flow between the inner and outer covers and drain out of the air cover assembly from the water drain hole, thereby minimizing gap corrosion between the inner and outer covers of the air cover assembly.
In the preferred mode of the invention, the drain hole is formed in the outer cover of the air cover assembly to extend from an edge of the crimped portion toward the air inlet, thereby avoiding accumulation of the water around the crimped portion between the inner and outer covers to facilitate ease of draining of the water.
The present invention will be understood more fully from the detailed description given hereinbelow and from the accompanying drawings of the preferred embodiments of the invention, which, however, should not be taken to limit the invention to the specific embodiments but are for the purpose of explanation and understanding only.
In the drawings:
Referring to the drawings, wherein like reference numbers refer to like parts in several views, particularly to
The gas sensor 1 consists essentially of a sensor element 2 sensitive to a gas to be measured (which will also be referred to as a measurement gas below) to produce an electrical signal as a function of the concentration of the measurement gas, a housing 3 in which the sensor element 2 is retained, and an air cover assembly 4 joined to a base end (i.e., an upper end, as viewed in
The air cover assembly 4 is made up of an inner cover 41 and an outer cover 42. The inner cover 41 is secured at an end thereof to the base end of the housing 3. The outer cover 42 is placed to surround a base end portion (i.e., an upper end portion, as viewed in
The air cover assembly 4 has formed therein air inlets 5 through which air is admitted inside the gas sensor 1.
The air cover assembly 4 has, as clearly shown in
The sensor element 2 is, as clearly shown in
The housing 3 has formed in an outer periphery thereof a thread 31 for installation of the gas sensor 1 in, for example, an exhaust pipe (not shown) of the automotive engine. When the gas sensor 1 is installed in the exhaust pipe, the top end portion (i.e. the lower end portion, as viewed in
The outer cover 42 has formed in the base end portion thereof air intake openings 425 through which the air is to be admitted thereinto.
The inner cover 41 is made up of a large-diameter portion 411 extending to the top end thereof and a small-diameter portion 412 extending to the base end thereof. The inner cover 41 has formed in the small-diameter portion 412 air intake holes 415 which face the air intake openings 425 radially of the air cover assembly 4.
The air cover assembly 4 also has a ventilation filter 50 made of, for example, a water-repellent filter 50 nipped between the inner cover 41 and the outer cover 42. The ventilation filter 50 constitutes the air inlets 5 along with the air intake openings 425 and the air intake holes 415.
The air cover assembly 4, as described above, has the four crimped portions 43 which are located at equi-intervals in the circumferential direction thereof to define the four air chambers 44, as clearly illustrated in
A rubber bush 13 is, as illustrated in
The gas sensor 1 is designed to have a drain path for water entering at the air inlets 5, as described below.
When the vehicle is splashed with water during traveling or washing, water may enter, as indicated by an arrow W, between the inner cover 41 and the outer cover 42 from the air inlets 5. The water then flows, as illustrated in
The number of the crimped portions 43 is not limited to four. The air cover assembly 4 may alternatively have at least one crimped portion 43 to join the inner cover 41 and the outer cover 42 together.
The outer cover 42 has at least one drain hole 421 which is, as clearly illustrated in
The crimped portion 45 of the air cover assembly 4, as referred to herein, is made up of portions of the inner and outer covers 41 and 42 which are, as illustrated in
Other arrangements are identical with those in the first embodiment, and explanation thereof in detail will be omitted here.
The inventor of this application performed corrosion tests in comparison of the gas sensor 1 with a conventional type of gas sensor.
The inventor prepared two types of test samples: one is the gas sensor 1 of the invention, and the other is a conventional type. Specifically, the inventor prepared, as can be seen from a graph of
Each of the corrosion tests was performed by installing one of the test samples in a pipe by screwing a thread (like the one, as denoted at 31 in
The air cover assembly of each of the test samples is made of stainless steel (SUS304).
After the above corrosion tests, the inventor disassembled the air cover assembly of each of the test samples, removed extraneous matter from opposed surfaces of the inner and outer covers of the air cover assembly, and observed the surfaces visually using a microscope to check them for cracks. When the crack was found in either of the surfaces of the inner and outer covers, it was decided that the surfaces of the inner and outer covers were corroded. This is because usually, when corrosion occurs between the inner and outer covers, it will cause the opposed surfaces of the inner and outer covers to darken, but however, it is difficult to determine whether such darkening has arisen from corrosion or stains on the surfaces. Therefore, when the crack arising from the corrosion was visually perceived, corrosion was determined as having occurred between the inner and outer covers.
Results of the corrosion tests are plotted in the graph of
While the present invention has been disclosed in terms of the preferred embodiments in order to facilitate better understanding thereof, it should be appreciated that the invention can be embodied in various ways without departing from the principle of the invention. Therefore, the invention should be understood to include all possible embodiments and modifications to the shown embodiments which can be embodied without departing from the principle of the invention as set forth in the appended claims.
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Mar 23 2007 | Denso Corporation | (assignment on the face of the patent) | / |
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